SummaryQuantum optics, the study of how discrete packets of light (photons) and matter interact, has led to the development of remarkable new technologies which exploit the bizarre properties of quantum mechanics. These quantum technologies are primed to revolutionize the fields of communication, information processing, and metrology in the coming years. Similar to contemporary technologies, the future quantum machinery will likely consist of a semiconductor platform to create and process the quantum information. However, to date the demanding requirements on a quantum photonic platform have yet to be satisfied with conventional bulk (three-dimensional) semiconductors.
To surmount these well-known obstacles, a new paradigm in quantum photonics is required. Initiated by the recent discovery of single photon emitters in atomically flat (two-dimensional) semiconducting materials, 2DQP aims to be at the nucleus of a new approach by realizing quantum optics with ultra-stable (coherent) quantum states integrated into devices with electronic and photonic functionality. We will characterize, identify, engineer, and coherently manipulate localized quantum states in this two-dimensional quantum photonic platform. A vital component of 2DQP’s vision is to go beyond the fundamental science and achieve the ideal solid-state single photon device yielding perfect extraction - 100% efficiency - of on-demand indistinguishable single photons. Finally, we will exploit this ideal device to implement the critical building block for a photonic quantum computer.

Quantum optics, the study of how discrete packets of light (photons) and matter interact, has led to the development of remarkable new technologies which exploit the bizarre properties of quantum mechanics. These quantum technologies are primed to revolutionize the fields of communication, information processing, and metrology in the coming years. Similar to contemporary technologies, the future quantum machinery will likely consist of a semiconductor platform to create and process the quantum information. However, to date the demanding requirements on a quantum photonic platform have yet to be satisfied with conventional bulk (three-dimensional) semiconductors.
To surmount these well-known obstacles, a new paradigm in quantum photonics is required. Initiated by the recent discovery of single photon emitters in atomically flat (two-dimensional) semiconducting materials, 2DQP aims to be at the nucleus of a new approach by realizing quantum optics with ultra-stable (coherent) quantum states integrated into devices with electronic and photonic functionality. We will characterize, identify, engineer, and coherently manipulate localized quantum states in this two-dimensional quantum photonic platform. A vital component of 2DQP’s vision is to go beyond the fundamental science and achieve the ideal solid-state single photon device yielding perfect extraction - 100% efficiency - of on-demand indistinguishable single photons. Finally, we will exploit this ideal device to implement the critical building block for a photonic quantum computer.

Max ERC Funding

1 999 135 €

Duration

Start date: 2018-01-01, End date: 2022-12-31

Project acronymACOUSEQ

ProjectAcoustics for Next Generation Sequencing

Researcher (PI)Jonathan Mark Cooper

Host Institution (HI)UNIVERSITY OF GLASGOW

Call DetailsProof of Concept (PoC), PC1, ERC-2016-PoC

SummarySince completion of the first human genome sequence, the demand for cheaper and faster sequencing methods has increased enormously. This need has driven the development of second-generation sequencing methods, or next-generation sequencing (also known as NGS or high throughput sequencing). The creation of these platforms has made sequencing accessible to more laboratories, rapidly increasing the volume of research, including clinical diagnostics and its use in directing treatment (precision medicine). The applications of NGS are also allowing rapid advances in clinically related fields such as public health and epidemiology. Such developments illustrate why sequencing is now the fastest-growing area in genomics (+23% p.a.). The activity is said to be worth $2.5B this year, and poised to reach ~$9B by 2020. In any workflow, prior to the sequencing reactions, a number of pre-sequencing steps are required, including the fragmentation of the DNA into smaller sizes for processing, size selection, library preparation and target enrichment. This proposal is specifically concerned with this latter area, namely DNA fragmentation – now widely acknowledged across the industry as being the most important technological bottleneck in the pre-sequencing workflow. Our new method for DNA fragmentation – involving using surface acoustic waves will enable sample preparation from lower sample volumes using lower powers. It also has the potential to allow the seamless integration of fragmentation into sequencing instrumentation, opening up the possibility of “sample to answer” diagnostics. In the near term this will enable the implementation of sample preparation pre-sequencing steps within the NGS instruments. In the longer term, our techniques will also enable us to develop methods for field-based DNA sequencing – as may be required for determining “microbial resistance” and informing the treatment of infectious disease in the face of the emergence of drug resistance.

Since completion of the first human genome sequence, the demand for cheaper and faster sequencing methods has increased enormously. This need has driven the development of second-generation sequencing methods, or next-generation sequencing (also known as NGS or high throughput sequencing). The creation of these platforms has made sequencing accessible to more laboratories, rapidly increasing the volume of research, including clinical diagnostics and its use in directing treatment (precision medicine). The applications of NGS are also allowing rapid advances in clinically related fields such as public health and epidemiology. Such developments illustrate why sequencing is now the fastest-growing area in genomics (+23% p.a.). The activity is said to be worth $2.5B this year, and poised to reach ~$9B by 2020. In any workflow, prior to the sequencing reactions, a number of pre-sequencing steps are required, including the fragmentation of the DNA into smaller sizes for processing, size selection, library preparation and target enrichment. This proposal is specifically concerned with this latter area, namely DNA fragmentation – now widely acknowledged across the industry as being the most important technological bottleneck in the pre-sequencing workflow. Our new method for DNA fragmentation – involving using surface acoustic waves will enable sample preparation from lower sample volumes using lower powers. It also has the potential to allow the seamless integration of fragmentation into sequencing instrumentation, opening up the possibility of “sample to answer” diagnostics. In the near term this will enable the implementation of sample preparation pre-sequencing steps within the NGS instruments. In the longer term, our techniques will also enable us to develop methods for field-based DNA sequencing – as may be required for determining “microbial resistance” and informing the treatment of infectious disease in the face of the emergence of drug resistance.

Max ERC Funding

149 995 €

Duration

Start date: 2017-05-01, End date: 2018-10-31

Project acronymACrossWire

ProjectA Cross-Correlated Approach to Engineering Nitride Nanowires

Researcher (PI)Hannah Jane JOYCE

Host Institution (HI)THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE

Call DetailsStarting Grant (StG), PE7, ERC-2016-STG

SummaryNanowires based on group III–nitride semiconductors exhibit outstanding potential for emerging applications in energy-efficient lighting, optoelectronics and solar energy harvesting. Nitride nanowires, tailored at the nanoscale, should overcome many of the challenges facing conventional planar nitride materials, and also add extraordinary new functionality to these materials. However, progress towards III–nitride nanowire devices has been hampered by the challenges in quantifying nanowire electrical properties using conventional contact-based measurements. Without reliable electrical transport data, it is extremely difficult to optimise nanowire growth and device design. This project aims to overcome this problem through an unconventional approach: advanced contact-free electrical measurements. Contact-free measurements, growth studies, and device studies will be cross-correlated to provide unprecedented insight into the growth mechanisms that govern nanowire electronic properties and ultimately dictate device performance. A key contact-free technique at the heart of this proposal is ultrafast terahertz conductivity spectroscopy: an advanced technique ideal for probing nanowire electrical properties. We will develop new methods to enable the full suite of contact-free (including terahertz, photoluminescence and cathodoluminescence measurements) and contact-based measurements to be performed with high spatial resolution on the same nanowires. This will provide accurate, comprehensive and cross-correlated feedback to guide growth studies and expedite the targeted development of nanowires with specified functionality. We will apply this powerful approach to tailor nanowires as photoelectrodes for solar photoelectrochemical water splitting. This is an application for which nitride nanowires have outstanding, yet unfulfilled, potential. This project will thus harness the true potential of nitride nanowires and bring them to the forefront of 21st century technology.

Nanowires based on group III–nitride semiconductors exhibit outstanding potential for emerging applications in energy-efficient lighting, optoelectronics and solar energy harvesting. Nitride nanowires, tailored at the nanoscale, should overcome many of the challenges facing conventional planar nitride materials, and also add extraordinary new functionality to these materials. However, progress towards III–nitride nanowire devices has been hampered by the challenges in quantifying nanowire electrical properties using conventional contact-based measurements. Without reliable electrical transport data, it is extremely difficult to optimise nanowire growth and device design. This project aims to overcome this problem through an unconventional approach: advanced contact-free electrical measurements. Contact-free measurements, growth studies, and device studies will be cross-correlated to provide unprecedented insight into the growth mechanisms that govern nanowire electronic properties and ultimately dictate device performance. A key contact-free technique at the heart of this proposal is ultrafast terahertz conductivity spectroscopy: an advanced technique ideal for probing nanowire electrical properties. We will develop new methods to enable the full suite of contact-free (including terahertz, photoluminescence and cathodoluminescence measurements) and contact-based measurements to be performed with high spatial resolution on the same nanowires. This will provide accurate, comprehensive and cross-correlated feedback to guide growth studies and expedite the targeted development of nanowires with specified functionality. We will apply this powerful approach to tailor nanowires as photoelectrodes for solar photoelectrochemical water splitting. This is an application for which nitride nanowires have outstanding, yet unfulfilled, potential. This project will thus harness the true potential of nitride nanowires and bring them to the forefront of 21st century technology.

Max ERC Funding

1 499 195 €

Duration

Start date: 2017-04-01, End date: 2022-03-31

Project acronymAdaSmartRes

ProjectAdapter for a commercial grade camera or a smart phone to perform depth resolved imaging

Researcher (PI)Adrian PODOLEANU

Host Institution (HI)UNIVERSITY OF KENT

Call DetailsProof of Concept (PoC), PC1, ERC-2016-PoC

SummaryThe proposal refers to a patented adapter that can transform a commercial grade digital camera or the camera in a smart phone into a depth resolved imaging instrument. Several adapters will be assembled, making use of optical coherence tomography (OCT) technology protected by some other of PI’s patents. The activity takes advantage of recent progress in commercial grade cameras in terms of their modes of operation as well as in terms of parameters of their devices, such as sensitivity and speed of their photodetector arrays.
Three versions of low cost functional OCT systems will be assembled as proof of concepts responding to needs of three possible markets that can be addressed by such an adapter: 1. En-face depth resolved, high transversal resolution microscope; 2. Fast cross sectioning imager. 3. Swept source volumetric analyser.
Industrial input comes from a company involved in professional eye imaging systems, a company already selling adapters for smart phones to perform medical imaging, a company specialised in digital photographic equipment and a company efficient in prototyping photonics equipment and handling medical images. Clinical input is provided by two specialists in the two highest potential medical imaging markets of the adapter serving ophthalmology and ear, nose and throat speciality.

The proposal refers to a patented adapter that can transform a commercial grade digital camera or the camera in a smart phone into a depth resolved imaging instrument. Several adapters will be assembled, making use of optical coherence tomography (OCT) technology protected by some other of PI’s patents. The activity takes advantage of recent progress in commercial grade cameras in terms of their modes of operation as well as in terms of parameters of their devices, such as sensitivity and speed of their photodetector arrays.
Three versions of low cost functional OCT systems will be assembled as proof of concepts responding to needs of three possible markets that can be addressed by such an adapter: 1. En-face depth resolved, high transversal resolution microscope; 2. Fast cross sectioning imager. 3. Swept source volumetric analyser.
Industrial input comes from a company involved in professional eye imaging systems, a company already selling adapters for smart phones to perform medical imaging, a company specialised in digital photographic equipment and a company efficient in prototyping photonics equipment and handling medical images. Clinical input is provided by two specialists in the two highest potential medical imaging markets of the adapter serving ophthalmology and ear, nose and throat speciality.

Max ERC Funding

149 300 €

Duration

Start date: 2017-06-01, End date: 2018-11-30

Project acronymADSNeSP

ProjectActive and Driven Systems: Nonequilibrium Statistical Physics

Researcher (PI)Michael Elmhirst CATES

Host Institution (HI)THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE

Call DetailsAdvanced Grant (AdG), PE3, ERC-2016-ADG

SummaryActive Matter systems, such as self-propelled colloids, violate time-reversal symmetry by producing entropy locally, typically converting fuel into mechanical motion at the particle scale. Other driven systems instead produce entropy because of global forcing by external fields, or boundary conditions that impose macroscopic fluxes (such as the momentum flux across a fluid sheared between moving parallel walls).
Nonequilibrium statistical physics (NeSP) is the basic toolbox for both classes of system. In recent years, much progress in NeSP has stemmed from bottom-up work on driven systems. This has provided a number of exactly solved benchmark models, and extended approximation techniques to address driven non-ergodic systems, such as sheared glasses. Meanwhile, work on fluctuation theorems and stochastic thermodynamics have created profound, model-independent insights into dynamics far from equilibrium.
More recently, the field of Active Matter has moved forward rapidly, leaving in its wake a series of generic and profound NeSP questions that now need answers: When is time-reversal symmetry, broken at the microscale, restored by coarse-graining? If it is restored, is an effective thermodynamic description is possible? How different is an active system's behaviour from a globally forced one?
ADSNeSP aims to distil from recent Active Matter research such fundamental questions; answer them first in the context of specific models and second in more general terms; and then, using the tools and insights gained, shed new light on longstanding problems in the wider class of driven systems.
I believe these new tools and insights will be substantial, because local activity takes systems far from equilibrium in a conceptually distinct direction from most types of global driving. By focusing on general principles and on simple models of activity, I seek to create a new vantage point that can inform, and potentially transform, wider areas of statistical physics.

Active Matter systems, such as self-propelled colloids, violate time-reversal symmetry by producing entropy locally, typically converting fuel into mechanical motion at the particle scale. Other driven systems instead produce entropy because of global forcing by external fields, or boundary conditions that impose macroscopic fluxes (such as the momentum flux across a fluid sheared between moving parallel walls).
Nonequilibrium statistical physics (NeSP) is the basic toolbox for both classes of system. In recent years, much progress in NeSP has stemmed from bottom-up work on driven systems. This has provided a number of exactly solved benchmark models, and extended approximation techniques to address driven non-ergodic systems, such as sheared glasses. Meanwhile, work on fluctuation theorems and stochastic thermodynamics have created profound, model-independent insights into dynamics far from equilibrium.
More recently, the field of Active Matter has moved forward rapidly, leaving in its wake a series of generic and profound NeSP questions that now need answers: When is time-reversal symmetry, broken at the microscale, restored by coarse-graining? If it is restored, is an effective thermodynamic description is possible? How different is an active system's behaviour from a globally forced one?
ADSNeSP aims to distil from recent Active Matter research such fundamental questions; answer them first in the context of specific models and second in more general terms; and then, using the tools and insights gained, shed new light on longstanding problems in the wider class of driven systems.
I believe these new tools and insights will be substantial, because local activity takes systems far from equilibrium in a conceptually distinct direction from most types of global driving. By focusing on general principles and on simple models of activity, I seek to create a new vantage point that can inform, and potentially transform, wider areas of statistical physics.

Max ERC Funding

2 043 630 €

Duration

Start date: 2017-10-01, End date: 2022-09-30

Project acronymAIDViC

ProjectAntibiotic intracellular delivery via virus-like carriers

Researcher (PI)Giuseppe BATTAGLIA

Host Institution (HI)UNIVERSITY COLLEGE LONDON

Call DetailsProof of Concept (PoC), PC1, ERC-2016-PoC

SummaryTaking inspiration from natural carriers, such as viruses, a new technology has been developed in
our laboratories part of an ongoing ERC starting grant project, Molecular Engineering of Virus-like
Carriers (MEViC). We created synthetic viruses using polymers and thus safer materials. They are
able of delivering high payload of specific drugs into cells with no detrimental effect. While testing for
anticancer therapies, we identified a synthetic virus capable of targeting almost exclusively
macrophages. We performed preliminary work showing that this can be successfully applied to
deliver antibiotics to rid of intracellular pathogens. This has now open a completely new possibility
whereas we can expand our technology for the treatment of several infections as well as to contribute
to the ongoing efforts in tackling antibiotic resistance.

Taking inspiration from natural carriers, such as viruses, a new technology has been developed in
our laboratories part of an ongoing ERC starting grant project, Molecular Engineering of Virus-like
Carriers (MEViC). We created synthetic viruses using polymers and thus safer materials. They are
able of delivering high payload of specific drugs into cells with no detrimental effect. While testing for
anticancer therapies, we identified a synthetic virus capable of targeting almost exclusively
macrophages. We performed preliminary work showing that this can be successfully applied to
deliver antibiotics to rid of intracellular pathogens. This has now open a completely new possibility
whereas we can expand our technology for the treatment of several infections as well as to contribute
to the ongoing efforts in tackling antibiotic resistance.

Max ERC Funding

149 062 €

Duration

Start date: 2017-07-01, End date: 2018-12-31

Project acronymAlCat

ProjectBond activation and catalysis with low-valent aluminium

Researcher (PI)Michael James COWLEY

Host Institution (HI)THE UNIVERSITY OF EDINBURGH

Call DetailsStarting Grant (StG), PE5, ERC-2016-STG

SummaryThis project will develop the principles required to enable bond-modifying redox catalysis based on aluminium by preparing and studying new Al(I) compounds capable of reversible oxidative addition.
Catalytic processes are involved in the synthesis of 75 % of all industrially produced chemicals, but most catalysts involved are based on precious metals such as rhodium, palladium or platinum. These metals are expensive and their supply limited and unstable; there is a significant need to develop the chemistry of non-precious metals as alternatives. On toxicity and abundance alone, aluminium is an attractive candidate. Furthermore, recent work, including in our group, has demonstrated that Al(I) compounds can perform a key step in catalytic cycles - the oxidative addition of E-H bonds.
In order to realise the significant potential of Al(I) for transition-metal style catalysis we urgently need to:
- establish the principles governing oxidative addition and reductive elimination reactivity in aluminium systems.
- know how the reactivity of Al(I) compounds can be controlled by varying properties of ligand frameworks.
- understand the onward reactivity of oxidative addition products of Al(I) to enable applications in catalysis.
In this project we will:
- Study mechanisms of oxidative addition and reductive elimination of a range of synthetically relevant bonds at Al(I) centres, establishing the principles governing this fundamental reactivity.
- Develop new ligand frameworks to support of Al(I) centres and evaluate the effect of the ligand on oxidative addition/reductive elimination at Al centres.
- Investigate methods for Al-mediated functionalisation of organic compounds by exploring the reactivity of E-H oxidative addition products with unsaturated organic compounds.

This project will develop the principles required to enable bond-modifying redox catalysis based on aluminium by preparing and studying new Al(I) compounds capable of reversible oxidative addition.
Catalytic processes are involved in the synthesis of 75 % of all industrially produced chemicals, but most catalysts involved are based on precious metals such as rhodium, palladium or platinum. These metals are expensive and their supply limited and unstable; there is a significant need to develop the chemistry of non-precious metals as alternatives. On toxicity and abundance alone, aluminium is an attractive candidate. Furthermore, recent work, including in our group, has demonstrated that Al(I) compounds can perform a key step in catalytic cycles - the oxidative addition of E-H bonds.
In order to realise the significant potential of Al(I) for transition-metal style catalysis we urgently need to:
- establish the principles governing oxidative addition and reductive elimination reactivity in aluminium systems.
- know how the reactivity of Al(I) compounds can be controlled by varying properties of ligand frameworks.
- understand the onward reactivity of oxidative addition products of Al(I) to enable applications in catalysis.
In this project we will:
- Study mechanisms of oxidative addition and reductive elimination of a range of synthetically relevant bonds at Al(I) centres, establishing the principles governing this fundamental reactivity.
- Develop new ligand frameworks to support of Al(I) centres and evaluate the effect of the ligand on oxidative addition/reductive elimination at Al centres.
- Investigate methods for Al-mediated functionalisation of organic compounds by exploring the reactivity of E-H oxidative addition products with unsaturated organic compounds.

Max ERC Funding

1 493 679 €

Duration

Start date: 2017-03-01, End date: 2022-02-28

Project acronymALEXANDRIA

ProjectLarge-Scale Formal Proof for the Working Mathematician

Researcher (PI)Lawrence PAULSON

Host Institution (HI)THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE

Call DetailsAdvanced Grant (AdG), PE6, ERC-2016-ADG

SummaryMathematical proofs have always been prone to error. Today, proofs can be hundreds of pages long and combine results from many specialisms, making them almost impossible to check. One solution is to deploy modern verification technology. Interactive theorem provers have demonstrated their potential as vehicles for formalising mathematics through achievements such as the verification of the Kepler Conjecture. Proofs done using such tools reach a high standard of correctness.
However, existing theorem provers are unsuitable for mathematics. Their formal proofs are unreadable. They struggle to do simple tasks, such as evaluating limits. They lack much basic mathematics, and the material they do have is difficult to locate and apply.
ALEXANDRIA will create a proof development environment attractive to working mathematicians, utilising the best technology available across computer science. Its focus will be the management and use of large-scale mathematical knowledge, both theorems and algorithms. The project will employ mathematicians to investigate the formalisation of mathematics in practice. Our already substantial formalised libraries will serve as the starting point. They will be extended and annotated to support sophisticated searches. Techniques will be borrowed from machine learning, information retrieval and natural language processing. Algorithms will be treated similarly: ALEXANDRIA will help users find and invoke the proof methods and algorithms appropriate for the task.
ALEXANDRIA will provide (1) comprehensive formal mathematical libraries; (2) search within libraries, and the mining of libraries for proof patterns; (3) automated support for the construction of large formal proofs; (4) sound and practical computer algebra tools.
ALEXANDRIA will be based on legible structured proofs. Formal proofs should be not mere code, but a machine-checkable form of communication between mathematicians.

Mathematical proofs have always been prone to error. Today, proofs can be hundreds of pages long and combine results from many specialisms, making them almost impossible to check. One solution is to deploy modern verification technology. Interactive theorem provers have demonstrated their potential as vehicles for formalising mathematics through achievements such as the verification of the Kepler Conjecture. Proofs done using such tools reach a high standard of correctness.
However, existing theorem provers are unsuitable for mathematics. Their formal proofs are unreadable. They struggle to do simple tasks, such as evaluating limits. They lack much basic mathematics, and the material they do have is difficult to locate and apply.
ALEXANDRIA will create a proof development environment attractive to working mathematicians, utilising the best technology available across computer science. Its focus will be the management and use of large-scale mathematical knowledge, both theorems and algorithms. The project will employ mathematicians to investigate the formalisation of mathematics in practice. Our already substantial formalised libraries will serve as the starting point. They will be extended and annotated to support sophisticated searches. Techniques will be borrowed from machine learning, information retrieval and natural language processing. Algorithms will be treated similarly: ALEXANDRIA will help users find and invoke the proof methods and algorithms appropriate for the task.
ALEXANDRIA will provide (1) comprehensive formal mathematical libraries; (2) search within libraries, and the mining of libraries for proof patterns; (3) automated support for the construction of large formal proofs; (4) sound and practical computer algebra tools.
ALEXANDRIA will be based on legible structured proofs. Formal proofs should be not mere code, but a machine-checkable form of communication between mathematicians.

SummaryThis interdisciplinary project investigates the transformation of Shii Islam in the Middle East and Europe since the 1950s. The project examines the formation of modern Shii communal identities and the role Shii clerical authorities and their transnational networks have played in their religio-political mobilisation. The volatile situation post-Arab Spring, the rise of militant movements such as ISIS and the sectarianisation of geopolitical conflicts in the Middle East have intensified efforts to forge distinct Shii communal identities and to conceive Shii Muslims as part of an alternative umma (Islamic community). The project focusses on Iran, Iraq and significant but unexplored diasporic links to Syria, Kuwait and Britain. In response to the rise of modern nation-states in the Middle East, Shii clerical authorities resorted to a wide range of activities: (a) articulating intellectual responses to the ideologies underpinning modern Middle Eastern nation-states, (b) forming political parties and other platforms of socio-political activism and (c) using various forms of cultural production by systematising and promoting Shii ritual practices and utilising visual art, poetry and new media.
The project yields a perspectival shift on the factors that led to Shii communal mobilisation by:
- Analysing unacknowledged intellectual responses of Shii clerical authorities to the secular or sectarian ideologies of post-colonial nation-states and to the current sectarianisation of geopolitics in the Middle East.
- Emphasising the central role of diasporic networks in the Middle East and Europe in mobilising Shii communities and in influencing discourses and agendas of clerical authorities based in Iraq and Iran.
- Exploring new modes of cultural production in the form of a modern Shii aesthetics articulated in ritual practices, visual art, poetry and new media and thus creating a more holistic narrative on Shii religio-political mobilisation.

This interdisciplinary project investigates the transformation of Shii Islam in the Middle East and Europe since the 1950s. The project examines the formation of modern Shii communal identities and the role Shii clerical authorities and their transnational networks have played in their religio-political mobilisation. The volatile situation post-Arab Spring, the rise of militant movements such as ISIS and the sectarianisation of geopolitical conflicts in the Middle East have intensified efforts to forge distinct Shii communal identities and to conceive Shii Muslims as part of an alternative umma (Islamic community). The project focusses on Iran, Iraq and significant but unexplored diasporic links to Syria, Kuwait and Britain. In response to the rise of modern nation-states in the Middle East, Shii clerical authorities resorted to a wide range of activities: (a) articulating intellectual responses to the ideologies underpinning modern Middle Eastern nation-states, (b) forming political parties and other platforms of socio-political activism and (c) using various forms of cultural production by systematising and promoting Shii ritual practices and utilising visual art, poetry and new media.
The project yields a perspectival shift on the factors that led to Shii communal mobilisation by:
- Analysing unacknowledged intellectual responses of Shii clerical authorities to the secular or sectarian ideologies of post-colonial nation-states and to the current sectarianisation of geopolitics in the Middle East.
- Emphasising the central role of diasporic networks in the Middle East and Europe in mobilising Shii communities and in influencing discourses and agendas of clerical authorities based in Iraq and Iran.
- Exploring new modes of cultural production in the form of a modern Shii aesthetics articulated in ritual practices, visual art, poetry and new media and thus creating a more holistic narrative on Shii religio-political mobilisation.

Max ERC Funding

1 952 374 €

Duration

Start date: 2018-01-01, End date: 2022-12-31

Project acronymARCTIC CULT

ProjectARCTIC CULTURES: SITES OF COLLECTION IN THE FORMATION OF THE EUROPEAN AND AMERICAN NORTHLANDS

Researcher (PI)Richard Charles POWELL

Host Institution (HI)THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE

Call DetailsConsolidator Grant (CoG), SH5, ERC-2016-COG

SummaryThe Arctic has risen to global attention in recent years, as it has been reconfigured through debates about global environmental change, resource extraction and disputes over sovereign rights. Within these discourses, little attention has been paid to the cultures of the Arctic. Indeed, it often seems as if the Circumpolar Arctic in global public understanding remains framed as a 'natural region' - that is, a place where the environment dominates the creation of culture. This framing has consequences for the region, because through this the Arctic becomes constructed as a space where people are absent. This proposal aims to discover how and why this might be so.
The proposal argues that this construction of the Arctic emerged from the exploration of the region by Europeans and North Americans and their contacts with indigenous people from the middle of the eighteenth century. Particular texts, cartographic representations and objects were collected and returned to sites like London, Copenhagen, Berlin and Philadelphia. The construction of the Arctic thereby became entwined within the growth of colonial museum cultures and, indeed, western modernity. This project aims to delineate the networks and collecting cultures involved in this creation of Arctic Cultures. It will bring repositories in colonial metropoles into dialogue with sites of collection in the Arctic by tracing the contexts of discovery and memorialisation. In doing so, it aspires to a new understanding of the consequences of certain forms of colonial representation for debates about the Circumpolar Arctic today.
The project involves research by the Principal Investigator and four Post Doctoral Researchers at museums, archives, libraries and repositories across Europe and North America, as well as in Greenland and the Canadian Arctic. A Project Assistant based in Oxford will help facilitate the completion of the research.

The Arctic has risen to global attention in recent years, as it has been reconfigured through debates about global environmental change, resource extraction and disputes over sovereign rights. Within these discourses, little attention has been paid to the cultures of the Arctic. Indeed, it often seems as if the Circumpolar Arctic in global public understanding remains framed as a 'natural region' - that is, a place where the environment dominates the creation of culture. This framing has consequences for the region, because through this the Arctic becomes constructed as a space where people are absent. This proposal aims to discover how and why this might be so.
The proposal argues that this construction of the Arctic emerged from the exploration of the region by Europeans and North Americans and their contacts with indigenous people from the middle of the eighteenth century. Particular texts, cartographic representations and objects were collected and returned to sites like London, Copenhagen, Berlin and Philadelphia. The construction of the Arctic thereby became entwined within the growth of colonial museum cultures and, indeed, western modernity. This project aims to delineate the networks and collecting cultures involved in this creation of Arctic Cultures. It will bring repositories in colonial metropoles into dialogue with sites of collection in the Arctic by tracing the contexts of discovery and memorialisation. In doing so, it aspires to a new understanding of the consequences of certain forms of colonial representation for debates about the Circumpolar Arctic today.
The project involves research by the Principal Investigator and four Post Doctoral Researchers at museums, archives, libraries and repositories across Europe and North America, as well as in Greenland and the Canadian Arctic. A Project Assistant based in Oxford will help facilitate the completion of the research.